DE3312586A1 - METHOD AND DEVICE FOR DETERMINING A CHARACTERISTIC PROPERTY - Google Patents

Description

Method and device for determining a characteristic property

The invention relates to a method and for determining a characteristic stream of particle-like material for determining radioactive materia rialstrom. The invention is for example in measuring radioactive material
radioactive ore can also be used in bulk sorting applications and in bulk material applications.

a device Ei property i η and especially 1 in one Matesung of the salary when sorting

Particle or product monitoring

In known methods for detecting gamma radiation of radioactive material, either a single or multiple scintillation detectors are used, those under a conveyor belt carrying the material or under the trajectory of the material in free flight are arranged. These detectors provide a measure of the radioactive mineral content of the material

A 20 2 0.4 / 5 - 6 -

available and allow the material in acceptable and to take care of the subdivisions to be rejected. animals, or continuously the proportion of a bulk material flow to monitor the material.

It has been suggested to pass the material through a ring detector or a number of them of detectors located around the material path, see, e.g., U.S. Patent 3,052,353. Other detector arrangements are disclosed in U.S. patents 4,317,521, 3,237,765, 3,075,641 and 2,717,693 and in British patent applications 1,479,972, - 1,218,844, 1,030,203, 960 408, 939 537, 855 678 and 658 572 are disclosed. In general, these methods have the inherent one Disadvantage that the determination effectiveness with-- ' the transverse position of a radioactive ore particle in relation to the scintillation detector or detectors is considerable varies and that in bulk sorting applications the determination efficiency also depends on the vertical position and the distance of a radioactive ore particle with respect to the detectors. This disadvantage manifests itself as an error in the calculation of the content of a particle or the Average content of a bulk material flow and can lead to the proportion estimate by a factor of up to 5 is faulty.

Known particle sorters have used a technique which consisted in compensating for the apparent fraction of the particle by a factor derived from the The transverse or lateral position of the particle in relation to the detectors is dependent, however, "" is this technique not always accurate and can cause a particle a goodness is assigned that differs from his

COPY

JJ 1 L. · ** KJ v_ »

A 20 204/5 - 7 -

actual goodness differs significantly.

The invention is based on the object of an improved method for determining a characteristic property in a flow of particle-like material . to accomplish. ··

The invention proposes a method for determining a characteristic property in particle-like material, a stream of the material being guided past a plurality of detectors, each of which responds to the characteristic property and the detectors being arranged in this way with respect to the material stream · are that the combined display of Completed ¹ - factors for a given, the characteristic property loading ..., sitting particles substantially from the position of the particle with respect to the detectors is independent when it passes by the detectors..

Thus, in accordance with the invention, the detectors are positioned so that their combined detection efficiency is substantially uniform, that is, substantially independent of the transverse position, depth or orientation of the given particle within the stream. ■ -. "'-

According to one embodiment of the invention, this is done thereby achieves that the material passes a plurality of detectors in a stream on a suitable carrier is funded on at least two opposite Sides of the beam, i.e. above and below the beam.

A 20 204/5 - - 8 -

The effective width of the carrier can be chosen such that the material flow is within a range within which the combined detector display is uniform is. - '

The detectors are preferably arranged in one plane which runs at right angles to the direction of movement of the material flow.

It is for example from the UK patent application 960 408 and from UK patent application 2 046 435A the applicant known to use a ring detector through which the particulate material gel. Apart from the fact that it is very expensive to provide a ring detector for a significant bulk flow of radioactive ore, a ring detector does not necessarily have a uniform display for a given particle at different levels Positions within the detector. The ring detector is effective in that it has a high proportion of emitted radiation, and this is desirable when working with low grade ore, but it is also equally desirable to have uniform detector efficiency.

Protective devices, e.g. a screen or a plate, may be provided below the upper detectors to prevent damage to the upper detectors protection caused by the material flow could.

The invention is particularly applicable to the fixed position radioactive particles in a stream of ore

CQPY

Ο I L

A 20 2Q4 / 5 - ..- - 9 - '

particles, and can be used in particle or bulk sorters or used with bulk material monitors.

In radioactive applications of the type described are the detectors scintillion detectors uV,. * can according to the invention within a radioactivity shield be arranged. This leads to a reduction in the background radiation count.

The invention also proposes an apparatus for use with particulate material comprising a plurality of of detectors, each of which has a characteristic Property in which the material responds, as well as facilities to convey the material past the detectors, those above and below the conveyor are arranged such that the combined display of the detectors for a given, the characteristic Particle possessing properties essentially of. independent of the position of the particle in relation to the detectors is when it gets past the detectors.

In one form of the invention the detectors are such arranged, i.e. they are essentially simultaneous to the characteristic property in the given Addressing particles. This can be achieved in that the detectors are arranged in a plane which substantially perpendicular to the direction of movement the conveyor runs.

In another embodiment of the invention are the detectors spaced from each other in the direction of movement of the material. The detector displays are combined, for example by simple Addition or superposition of the corresponding signals,

BAD ORIGINAL yyy)

A 20 204/5 - 10 -

which are time-delayed or time-compensated in some other way in order to reduce the speed of the movement of the material flow to be taken into account. In this way the combined signal is made independent of time and depends only on the strength of the characteristic property in the particle.

The combined display characteristics of the detectors can be essentially constant over a central area containing the conveying devices, and may have sections of reduced effectiveness or sensitivity on opposite sides of the conveyors exhibit.

The principles of the invention are suitable for installation in a sorting device and also in a monitoring device for quality assurance monitoring at, for example the rejection part a bulk ore sorter. In such a sorter, the acceptable fraction contains the ore stream Components with a quality above a limit value. Therefore, the quality of the reject rate is below the Limit value. Therefore, taking into account the fact that the device according to the invention is one of the particle position has independent display that Monitoring the reject or the acceptable Proportionately carried out by taking the combined uniform display for a given quality as a reference value treated and equated to the limit value. An upward or downward deviation in the measured quality from the reference value, depending on the case, shows

COPY

A ... 20 204/5. - -1-1 -

then a bad function of the sorting device and if this bad function occurs, a suitable alarm signal can be triggered, for example an audible or visible signal.

Further features, "details and advantages of the invention can be found in the following description of preferred" Embodiments of the invention and based on the drawing ". Here show:

Fig. 1 is a partially sectioned view of a Section of a sorting system for radioactive material in accordance with the invention;

Figure 2 is a schematic side view of the system according to Fig. 1 with superimposed detector characteristics ikaund

Figure 3 is a series of graphs illustrating the advantages possible by the invention.

1 shows a conveyor belt 10 which conveys a bulk material flow of ore 12 past scintillation detectors 14, which are arranged below the belt, and on scintillation detectors positioned above the belt 16. A protective screen or plate 18 is positioned below the detectors 16 and above the ore flow protects the detectors from damage that would otherwise be caused by the ore particles on the detectors could. A rectangular leaf shield 20 surrounds the Detectors 14 and 16 and the ore flow passed between them. The output signals from the detectors become one

A 20 204/5 - - 12 -

Logic unit 21 out.

The device according to FIG. 1 can work in the sorting mode, in which case the logic unit 2.1 stops the operation a gate, not shown, or another device that acts on the ore stream 12 and controls him separates into acceptable and reject fractions. It is also possible for the device as a bulk material ore monitor works for a sorter that streams the ore 12 surrenders as his share. The quality of the ore is then monitored and if one is exceeded predetermined value, which indicates that the sorter is malfunctioning, the logic unit can select a suitable Trigger an alarm or a corresponding corrective action.

The detectors 14 and 16 have predetermined dimensions and are mutually and with respect to each other. of the ore flow so "positioned that the combined display of the Detectors essentially independent of a radioactive particle passing the detectors on the position of the particle in the ore stream. In other words, the detectors represent a relative uniform determination efficiency for any radioactive Particles available, the display signal of the detectors essentially independent of the Q.uerposition, the depth or the orientation of the radioactive particle is in the stream.

Fig. 1 shows a bulk material stream 12 of ore. Of course can radioactive particles within the Current in any position within the entire material be, and the arrangement of the sci ntillation

COPY

OOI L- UU

A 20 204/5 - 1-3 -

Detectors takes into account the detector geometry that relative arrangement of the particle within the flow and the radiation absorption by the particle by Material above and below the particle.

When the features of the invention for use in a Particle sorter are adapted, the positioning of the scintillation detectors is chosen such that the transverse displacement of the particle and also a non-uniform distribution of radioactive material is taken into account, for example particles that usually deaf material, but a small one Area of radioactive material on the surface. Of course, the task of the inventor becomes faster when the stream 12 reaches a uniform depth which is predetermined for the detector configuration.

For example, FIG. 2 shows detectors 14 and 16 and in dashed outline on the belt superimposed the Determination characteristics of the three lower detectors. The three upper detectors have similar characteristics ka, however these have been omitted for the sake of "clarity".

Each detector characteristic is essentially a Gaussian curve. In this case, the two outer detectors (14A, 16A) are relatively large, e.g. with an effective receptor surface of about 9 square inches (approx. 58 cm ² ), and therefore their peak efficiencies are higher than those of the middle detector (14B, 16B) with one.

A 20 204/5 "- 14 -

Receptor surface area of about 6 square inches (about 39 cm ² ). It has been found that the combination of the two large outer detectors and a relatively smaller inner detector with suitable mutual spacing creates a surprisingly uniform combined determination characteristic.

Fig. 1 illustrates a practical case of bulk ore sorting in which the flow of material is efficient Bulk particles width of about 400 mm and a height of about 100 mm. With this configuration are three detectors 14 transversely under the conveyor belt, i.e. in a line perpendicular to the direction of travel of the conveyor belt runs, and three detectors are arranged in a line that is directly above the lower line of detectors runs. The center-to-center distance and the relative positioning of the detectors are calculated in such a way that the integrated during the movement of a particle through the effective counting zone of the detectors Exit of the detectors essentially from the transverse direction of the particle on or above the belt and is also independent of the particle orientation. However, the exact positions of the detectors are determined to a large extent in an actual installation Trial and experiment determined.

First of all, therefore, the detectors on each side will be like this arranged to have a uniform combined characteristic and second, the positions of the two sets of detectors are on the opposite one Sides of the conveyor belt varied so that the combined Display both sets of detectors for one

COFY

vJ O

A 20 204/5. - 15 -

Particle is substantially uniform, independently on the position of the particle between the two sets of detectors.

In addition, the width of the belt is designed in such a way that that the ore flow is within the central range of the uniform readings of the detectors and not encompasses the end areas of the display curve, where there is a reduction in the effectiveness of the display.

Fig. 2 contrasts particles 22 in four different planes A, B, C and D and at different transverse positions the central line 24 of the conveyor belt da *.

Fig. 3 represents curves 1 to 6 of the determination efficiency as a function of the transverse position of the particle 22 on the conveyor belt, with reference to the center line 24, in each of levels A to D.

Curves 1 to 4 are determination effectiveness curves, achieved with a conventional detector configuration in the case where only the three detectors are used which are the same size and are arranged below the conveyor belt. . „._ Curves 1 to 4 are generally the same "" "* ■" - form, however, will be the most effective (Curve 1) reached when the particle 22 lies in the lowest level A, which is closest to the detectors is. When the particle 22 is in the plane D furthest from the detectors, the determination efficiency is lowest (curve 4). The relative

A 20 204/5 - 16 -

Mood effectiveness for the conventional detector configuration changes for levels A to D for a particle on the center line 24 over the range from 65 % to 20 %, ie by a ratio of 3:25:

Curves 5 and 6 represent the relative determination efficiency when suitable configurations of detectors M and 16 of the type described in connection with FIG. 3, which are arranged below and above the conveyor belt 10, respectively, are used. Curve 5 gives the determination efficiency for the particle 22 in plane A or D, while curve 6 is a similar curve for the particle in plane B or C. With this detector configuration it can be seen that the relative detector efficiency varies over the range of 95% to 70 % , that is, by a ratio of 1: 35: 1.

It follows that the detector configuration shown in FIGS. 1 and 2 provides a more accurate determination of the quality individual particles of radioactive material in the stream and therefore better defined sorting characteristics ka in the case of a particle or bulk material sorter, and in the case of a bulk material monitor more precise through cutting quality measurements results.

OOPY

Claims (12)

Expectations Method and device for determining a characteristic property Method for determining a characteristic Property in particulate material, where a Material stream (12) is moved past a plurality of detectors (14, 16), each of which points to the characteristic property responds, characterized in that the detectors (14, 16) in relation to the material flow (12) are arranged in such a way that the combined display of the detectors (14, 16) for a given, the characteristic property owning particle essentially on the position of the particle with respect to the detectors (14, 16) is independent when it passes the detectors (14, 16). A 20 204/5 - 2 » 2 .. The method according to claim 1, characterized in that
that the material (12) is conveyed in a stream on a suitable carrier (10) past the detectors (14, - 16) which are arranged above and below the carrier (10). 3. A method for monitoring the operation of a bulk goods sorter, characterized in that the
The reject fraction of the ore sorter is monitored using the method of claim 1 or 2, the reject fraction forming the material flow, and that an alarm condition is initiated when the combined detector reading exceeds a predetermined reference value. 4. Device for use with particulate material, with a plurality of detectors (14, 16),
each of which responds to a characteristic property in the material, as well as means (TO) for conveying the material to the
Detectors (14, 16) over, characterized in that
that the detectors (14, 16) above and below
of the conveyors (10) are arranged such that the combined display (curve 5, curve 6) of the
Detectors (14, 16) for a given particle having the characteristic property is essentially independent of the position of the particle with respect to the detectors (14, 16) when it passes it. 5. Apparatus according to claim 4, characterized in that that the detectors (14, 16) are essentially simultaneous on the characteristic property in that address given particles. COPY A 20 204/5 _: ._.- 3 - 6. Apparatus according to claim 4 or. 5, characterized in that the detectors (14, 16) in one Plane are arranged that are substantially rectangular runs opposite the direction of movement of the conveyor (10). 7. Device according to claim 4, characterized in that that the detectors (14, 16) move from one another ■ * Direction of movement of the material arranged at a distance s i η d. 8. Device according to one of claims 4 to 7, characterized in that the detectors (14, Ki) and at least some of the conveying devices (10) are arranged within a shield (20) --_ 9. Device according to one of claims 4 to 8, characterized in that the width of the conveyors (10) is such that the material on the conveyors (10) is within a range in that the combined detector display (curve 5, curve 6) is uniform, while the combined detector display effectiveness "decreases outside of this range. 10. Device according to one of claims 4 to 9, characterized ■ characterized in that three detectors (16) above the conveyor devices (10) and three detectors. (14) are arranged below the conveying devices (1C) in such a way that in each case two relatively large detectors (14A, 16A) arranged on both sides of an inner j relatively smaller detector (14B, 16, B) j are. - BATH ORIGINAL A 20 204/5 - 4 - 11. ore sorter, characterized in that it contains a device according to one of claims 4 to 10 and a logic unit (21) to which the combined detector display (curve 5, curve 6) is applied, the logic unit (21) means for separating the Ore stream (12) controls in acceptable and reject fractions. 12. Monitoring device, characterized in that it is a device according to one of the claims 4 to 10 and a logic unit (21) on which the combined detector display (curve 5, Curve 6) is present, the logic unit (21) initiating an alarm condition if the combined Detector reading exceeds a predetermined value. copy